In 1984, the U.S. Geological Survey (USGS) conducted a reconnaissance cruise L9-84-CP aboard the R/V S.P. LEE along the northern Ratak Ridge, Marshall Islands (Fig. 1). Preliminary geochemical results from the cruise show that ferromanganese crusts (Mn crusts) on the submarine slopes of seamounts, and islands may have potential for commercial exploitation (Schwab and others, 1985). In this report we present shipboard data and laboratory analyses for rock samples collected on cruise L9-84-CP. This report should supplement the reports of Schwab and Bailey (1985) and Schwab and others (1985).

A total of 5410 km of 12-kHz and 3.5-kHz seismic-reflection data, and q O 730 km of 80-in³ and 148-in³ airgun seismic-reflection data were collected on cruise L9-84-CP (Schwab and Bailey, 1985). Eighteen sample stations were occupied; 13 dredge hauls and 3 box cores were collected (Table 1). These samples are available at the USGS Branch of Pacific Marine Geology offices in Menlo Park, California. Data presented in this report should encourage a more extensive field investigation and serious economic and technical evaluation of Mn crusts within the Marshall Islands area.

Ferromanganese-oxide precipitates that encrust hard substrate on the submarine flanks of seamounts, guyots, atolls, islands, and linear volcanic ridges, have been known for several decades (Cronan, 1977; Frazer and Fisk, 1980) but were not studied in a systematic way until the West German MIDPAC expedition of 1981 (Halbach and others, 1982). Unlike abyssal ferromanganese nodules, Mn crusts contain higher concentrations of the economically attractive metals, cobalt and platinum (Toth, 1980; Craig and others, 1982; Halbach and others, 1984; Hein and others, 1985). Mn crusts are predominantly hydrogenous in origin, in contrast to abyssal ferromanganese nodules which also have a substantial diagenetic input (Halbach and others, 1981).

In order for a Mn crust deposit to be economically attractive, it must be of high grade in recoverable metals, thick, and aerially extensive. During a 1984 workshop in Honolulu, East-West Center, engineers and geologists determined that Mn crusts must have an average thickness of 4 cm and a cobalt content greater than 0.8 percent of the dry weight (8000 ppm) to be considered for exploitation. The metals other than cobalt that are likely to be recovered from such a deposit include nickel, manganese, zinc, lead, phosphorous, and platinum. Preliminary chemical analyses of the Mn crusts collected during cruise L9-84-CP (Schwab and others, 1985) show that the average concentrations of metals within them are comparable with the mean metal contents of Mn crusts from the eastern Mid-Pacific Mountains and northern Line Islands Ridge, areas of high economic potential (Halbach and Manheim, 1984; Hein and others, 1985). Based on the extent of sea floor above 2400 m water depth and the age of the substrate, resource experts at the East- West Center in Honolulu placed the Marshall Islands as second in economic potential for Mn crusts as compared to the Mn crust resources within all other U.S. Pacific states, trust territories, and possessions (A.L. Clark, personal communication). Based on these and other geologic and oceanographic criteria, Hein and others (1986a) placed the Marshall Islands first with respect to U.S. interests.

For convenience, several previously unnamed seamounts have been named (see Hein and others, 1986b), including Erikub Seamount, Utirik Seamount, Bikar Guyot, and Ratak Guyot. We use these names informally in this report.